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Article Abstract
Nitrous acid (HONO) constitutes an essential gaseous pollutant and a significant reservoir of hydroxyl radicals (OH), which are crucial for atmospheric oxidation capacity. Environmentally persistent free radicals (EPFRs), long-lived in particulate matter, may promote HONO formation via reactions with NO, although the mechanisms remain incompletely elucidated. In this study, the heterogeneous formation of HONO was explored through reactions between NO and diesel soot collected during a field campaign, focusing on the role of EPFRs. EPFRs in diesel soot, primarily composed of carbon-centered radicals (CCRs) within the elemental carbon (EC), were present at 5.40 × 10 ± 9.60 × 10 spins·m. The combination of CCRs in EC with NO to form surface nitro compounds (RONO) was initially observed and served as the rate-limiting step. Furthermore, the photolysis of carboxyl compounds (ROOH) in organic carbon (OC) generated OH, which reacted with RONO to enhance HONO formation. Gradient RH experiments revealed that HO facilitates HONO formation by enhancing NO adsorption or acting as an OH donor. The results indicate that, in typical urban environments, besides HCHO photolysis, EPFRs in diesel soot significantly contribute to HONO formation, playing a major role in OH production with a rate of ∼10 molecules·cm·s at RH 40-60% under vehicle-related EPFR concentrations (∼10 spins·m, observed in Xi'an, China). This study highlights a novel HONO formation mechanism based on the synergistic effects of OC and EC in soot and underscores the critical role of EPFR-mediated heterogeneous HONO formation in the atmospheric oxidative capacity.
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